Hydraulic arrangement for a lifting unit

ABSTRACT

A hydraulic arrangement for lifting and/or lowering at least one implement carrying arm on an agricultural machine. The arrangement comprises an inlet hydraulic line and an outlet hydraulic line connecting a fluid pump and a fluid reservoir respectively to a first valve means, said arrangement comprising at least one dual acting hydraulic cylinder for lifting/and or lowering the implement carrying arm. The at least one cylinder is connected to the first valve means allowing the cylinder to be switched between a single acting mode wherein the arm can be lifted and a double acting mode wherein the arm can be lifted and lowered.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 13/997,391, filed Jun. 24, 2013, which is a National Stage of International Application No. PCT/EP2011/072721 which claims priority to U.K. Application No. 1021961.6, filed Dec. 24, 2010, entitled “HYDRAULIC ARRANGEMENT FOR A LIFTING UNIT”.

TECHNICAL FIELD

This invention relates to a hydraulic lifting and lowering arrangement on a self propelled machine. More specifically the invention relates to a lifting and lowering arrangement of an implement carrying arm on an agricultural machine.

BACKGROUND

Agricultural machines, such as forage harvesters for example may be equipped with implements to be worked over the ground. The implement may carry out processes such as cutting grass, grain, maize or working the soil. Owing to the variety of working processes and terrain conditions a self propelled machine must be capable of carrying and moving a wide range of different implements of varying weights under different working conditions.

For some processes such as heavy soil tillage, the full weight of the implement rests on the ground. In other working conditions the full weight of the implement will be carried by the machine so that the implement does not touch the ground. This would be the case for example with maize harvesting. In other cases, such as grass harvesting, part of the weight of the implement is carried by the machine and part of the weight is borne by the ground.

Typical lifting arrangements on agricultural machines comprise one or more carrying arms to which an implement is attached and which can be moved to lift and lower an implement. A carrying arm is movable around one, or more pivot points by one or more hydraulic cylinders. There is therefore mechanical and hydraulic friction with such an arrangement. The amount of friction will depend on the direction of movement of the arms and will be different from the extending and retracting stroke of the cylinders which will lead to hysteresis.

Some implements which are attached to the machine are to be moved in one direction only (upwards) since to move the implement downwards using the cylinders could damage the ground or implement. Such implements require a single acting hydraulic cylinder or a double acting hydraulic cylinder that can be used in single acting mode. Typically, the hydraulic arrangement is arranged such that pressurisation of the cylinder extends the piston rod which raises a carrying arm and implement. When the cylinder is not pressurised the piston retracts slowly under the weight of the attached implement lowering the carrying arm and implement to the ground.

Owing to mechanical and hydraulic friction in a hydraulic arrangement, the weight of the attached implement may not be sufficient to contract the cylinder to lower the carrying arm. Such implements will require a double acting hydraulic cylinder so that the implement can be both lifted and lowered to the ground by controlling the pressure exerted on the hydraulic cylinders.

Also, for maintenance of a forage harvester it is necessary to dismount an intake from the carrying arms to allow maintenance work to the machine to be carried out. This means that there is no weight attached to the carrying arms and therefore if a single acting hydraulic cylinder is used the cylinders cannot be retracted and therefore the carrying arms cannot be lowered unless an external force is applied to the carrying arms.

It is a known problem to retract a double acting cylinder which is connected to a single acting valve arrangement as it must be pushed in manually. This means the attached carrying arm must be pushed downwards manually if it is to be lowered.

Alternatively, if the carrying arm has already been detached for maintenance purposes, the attachment rods (to which the carrying arms are mounted) must pushed in manually. It is known that hydraulic cylinders used on medium or large size machines cannot be pushed in manually because the frictional force is so high that it can not be overcome by human force alone.

It is an aim of the invention to overcome the problem set out above and provide a hydraulic arrangement for moving a carrying arm on an agricultural machine in which the function of the hydraulic cylinders can be easily switched between a single acting mode and a double acting mode using a single valve arrangement.

It is a further aim of the invention to provide an hydraulic arrangement which is suitable for moving both heavy and light implements attached to a carrying arm in a manner that the pressure required to lift a light implement will be raised artificially to the same level that is required to lift a heavy implement.

In accordance with the invention there is provided an hydraulic arrangement for lifting and/or lowering at least one implement carrying arm on an agricultural machine having the features of claim 1.

In case of maintenance and service it may be necessary for a person to position himself under an implement mounted to a forage harvester. In order to prevent serious injuries due to an operator lifting or lowering the implement, there is legislation stating that it must be possible to lock and hold the at least one hydraulic cylinder so that its movement does not caused injury.

Preferably, the hydraulic arrangement comprises a blocking valve to prevent unwanted movement of the at least one cylinder.

Further preferred features of the invention are set out in the dependent claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described by example only, with reference to the following drawings in which:

FIG. 1 is a circuit diagram of the hydraulic arrangement in accordance with the invention,

FIG. 2 is a circuit diagram of the hydraulic arrangement of FIG. 1 in which the circuit is single acting and is suitable for use with a light implement,

FIG. 3 is a circuit diagram of the hydraulic arrangement of FIG. 1 in which the circuit is single acting and is suitable for use with a heavy implement,

FIG. 4 is a is a circuit diagram of the hydraulic arrangement of FIG. 1 in which the circuit is double acting,

FIG. 5 is a circuit diagram of the hydraulic arrangement of FIG. 1 in which the circuit is in a locked position.

DETAILED DESCRIPTION

FIG. 1 is an hydraulic circuit 1 for controlling movement (lifting and/or lowering) of at least one carrying arm on an agricultural machine, for example a forage harvester. A variety of implements such as a mower, plough or crop cutter may be attached to the carrying arm.

The carrying arm, or carrying arms (not shown) are connected to one or more dual acting cylinders 15. In FIG. 1, two dual acting cylinders are shown for use with two carrying arms. Both the piston end 15 a and cap end 15 b of the cylinders are connected to a first valve means 12 which is a 4/3 directional valve. Directional valve 12 is connected by hydraulic line 25 to a blocking valve 13 and a second valve means 14. Second valve means 14 is a 4/4 directional control valve. Valve 14 is connected to a pump 18. Valves 12, 13, 14 are also connected to fluid reservoirs 26 by hydraulic line 27. Valves 12 and 13 are shown as being manually operable by an operator pushing them, however other valves such as mechanically, electrically or pneumatically operated valves could also be used. Valve 14 is electrically operable by means of signal from an ECU 22 (explained below).

When an implement is fitted to the carrying arms and the machine is travelling over undulating surface conditions the weight distribution between the ground and the machine is kept constant by a control system. The control system comprises a pressure transducer 21, an ECU unit 22 and a control panel 23. The transducer 21 constantly measures the pressure in hydraulic line 24 and the ECU continually compares this value with a pressure entered into the control panel 23 by the operator. If the pressure in hydraulic line 24 is too high, control valve 14 can be activated to lower the implement. If the pressure is too low, control valve 14 can be activated to lift the implement. Such a control system is well known and does not form part of the invention and is therefore excluded from FIGS. 2 to 5.

FIG. 2 shows valve 12 in a first position 12 a for when a light implement, such as a grass cutting implement is attached to the carrying arms. Valve 13 is in the open position 13 a. When valve 14 is moved from the closed position 14 b into the open position 14 a, fluid is pumped through line 25. With valve 12 in position 12 a both the piston end 15 a and cap end 15 b of cylinders 15 are connected to line 25 and the pressure in cap end 15 b can be increased pushing the piston out and raising the carrying arm and attached implement. This results in quick movement and high pressure facilitating easier control because the distance between the pressure level that needs to be controlled and the pressure level that is caused by hysteresis has been increased. The system is single acting. By moving valve 14 into position 14 c, the weight of the implement will cause the cylinders 15 to retract, moving fluid from the cap ends 15 b through line 25 to the reservoir 26. Also the piston ends of the cylinders will be filled. The actual lowering speed can be adjusted easily as valve 14 is a proportional valve.

The accumulator 16 serves to absorb vibrations caused by the machine running over undulating ground and can be connected and disconnected by valve 17 in order to react to different operating conditions. It also supports the pressure control system described above because the hydraulic accumulator in conjunction with the cylinder acts similar to a mechanical spring. If the valve is connected any changes in pressure will fed directly to the accumulator. If the valve 17 is disconnected constriction 20 serves as a pressure balance. For example, if the accumulator is switched off and a new heavier implement is attached, constriction 20 prevents carrying arm crashing down. Likewise, if a lighter implement is attached it prevents the carrying arm lifting.

FIG. 3 shows the hydraulic arrangement when valve 12 is moved into position 12 c for when a heavy attachment, such as a corn header is attached to the carrying arms. In position 12 c cylinder piston ends 15 a are connected to hydraulic line 27 and the hydraulic line 25 is connected to the cylinder cap ends 15 b. Valve 13 is in the open position 13 a. This arrangement is single acting. When valve 14 is moved to open position 14 a pressure only acts on the cap end sides 15 b of the pistons allowing a large force to be exerted on the pistons, to extend it, thus raising the arm. At the same time pressure on the piston side 15 a is released through line 27 to reservoirs 26. When valve 14 is moved to position 14 c the cylinders can retract under the weight of the attached implement and the carrying arms lower as fluid flows from the cylinders through line 27 to the reservoir 26.

FIG. 4 shows the hydraulic arrangement when valve 12 is moved into position 12 b so that line 27 is connected to the piston ends 15 a of the cylinders 15 and line 25 is connected to the cap ends 15 b of the cylinders. Valve 13 is in the open position 13 a. With this arrangement the cylinders 15 are double acting. When valve 14 is moved to open position 14 a fluid can flow through line 25 to the cap ends 15 b exerting a pressure on the piston and extending the pistons lifting the carrying arms and an attached implement. Fluid in piston ends 15 a can flow through line 27 to reservoir 16. If the valve 14 is then moved to position 14 b, the weight of the attached implement will cause pistons 15 to retract and fluid will flow from the cap ends 15 b to reservoir 26. If, however, there is no implement attached to the carrying arms the weight of the arms alone will not provide a strong enough force to retract the cylinders and the carry arms will remain in a lifted position. It may be necessary to lower the arms to allow maintenance work to be done to the machine. In order to lower the arms, the hydraulic arrangement can be used to provide a force on the piston to retract the pistons.

With the valve 12 in position 12 c and valve 14 in position 14 b, the pump 18 can be used to pump fluid through line 27 to the piston ends 15 a of the cylinders to provide a force on the piston to retract the piston and thus lower the carrying arms.

FIG. 5 shows the case where blocking valve 13 is in the closed position 13 b. Valve 13 can be manually pushed by the operator into the closed position. Essentially the cylinders 15 are locked in position so that the carrying arms cannot move. This is a safety measure so that it is safe for a person to carry out maintenance, or checks close to the carrying arms without there being any danger of movement of the arms. 

At least the following is claimed:
 1. A combine harvester, comprising: a chassis; a feeder house mounted to the chassis; a header mounted to the feeder house; and a control system, comprising: a pump; a fluid reservoir; a hydraulic cylinder comprising a cap-end port, a piston-end port, and a piston and rod assembly that is bi-directionally moveable between the cap-end and piston-end ports, the hydraulic cylinder affixed to the feeder house and arranged to cause a raising and lowering of the feeder house and the header; and a cylinder circuit coupled to the cap-end and piston-end ports and switchably configurable between a first mode and a second mode of header raising operations, the cylinder circuit comprising: a first multi-position valve coupled between an outlet of the pump and the cap-end port; and a second multi-position valve coupled to the piston-end port, wherein in the first mode, a first fluidic circuit is established between the pump, the multi-position valve in a first position, and the cap-end port, and the piston-end port, the second multi-position valve in a first position, and the fluid reservoir, wherein in the second mode, a second fluidic circuit is established between the pump, the multi-position valve in the first position, and the cap-end port, and the piston-end port, the second multi-position valve in a second position, and the cap-end port; a control circuit comprising: a controller coupled to the cylinder circuit; and a sensor coupled to the controller and configured to sense an operational parameter of the cylinder circuit, wherein the controller is automatically configured to cause a switching of the cylinder circuit between the first and second modes based on the operational parameter sensed by the sensor.
 2. The combine harvester of claim 1, wherein based on hydraulic fluid flow in the second fluidic circuit, the hydraulic cylinder causes the header to raise at a faster speed in the second mode than in the first mode.
 3. The combine harvester of claim 1, wherein based on hydraulic fluid flow in the first fluidic circuit, the hydraulic cylinder causes the header to raise with higher force in the first mode than in the second mode.
 4. The combine harvester of claim 1, wherein the operational parameter comprises pressure at the first port.
 5. The combine harvester of claim 1, wherein the second multi-position valve comprises an actuator, wherein the controller is automatically configured to cause the switching of the cylinder circuit by sending a signal to the actuator of the second multi-position valve.
 6. A combine harvester, comprising: a chassis; a feeder house mounted to the chassis; a header mounted to the feeder house; and a control system, comprising: a pump; a fluid reservoir; a hydraulic cylinder comprising a cap-end port, a piston-end port, and a piston and rod assembly that is bi-directionally moveable between the cap-end and piston-end ports, the hydraulic cylinder affixed to the feeder house and arranged to cause a raising and lowering of the feeder house and the header; and a cylinder circuit coupled to the cap-end and piston-end ports and switchably configurable between a first mode and a second mode of header raising operations, the cylinder circuit comprising: a first multi-position valve coupled between an outlet of the pump and the cap-end port; and a second multi-position valve coupled to the piston-end port, wherein in the first mode, a first fluidic circuit is established between the pump, the multi-position valve in a first position, and the cap-end port, and the piston-end port, the second multi-position valve in a first position, and the fluid reservoir, wherein in the second mode, a second fluidic circuit is established between the pump, the multi-position valve in the first position, and the cap-end port, and the piston-end port, the second multi-position valve in a second position, and the cap-end port; a control circuit comprising: a controller coupled to the cylinder circuit; and a first user interface, wherein the controller is configured to cause a switching of the cylinder circuit between the first and second modes based on operator input received at the first user interface.
 7. The combine harvester of claim 6, further comprising a second user interface and a sensor coupled to the controller, wherein the second user interface is configured to present an operational parameter sensed by the sensor prompting the receiving of the operator input.
 8. The combine harvester of claim 7, wherein the second user interface is configured to present the operational parameter visually, audibly, or a combination of visually and audibly.
 9. The combine harvester of claim 6, wherein the second multi-position valve comprises an actuator, wherein the controller is configured to cause the switching of the cylinder circuit by sending a signal to the actuator of the second multi-position valve.
 10. The combine harvester of claim 1, wherein the control system comprises another multi-port hydraulic cylinder coupled affixed to the feeder house and coupled to the cylinder circuit to enable a raising and lowering of the feeder house and the header.
 11. A method of controlling a hydraulic header that is coupled to a feeder house of a combine harvester, the method comprising: providing, by a pump, a flow of hydraulic fluid through a first plurality of components fluidly coupled together, wherein in a first mode, the first plurality of components comprises a pump, a first-multi-position valve, a cap-end port of a hydraulic cylinder, a piston-end port of the hydraulic cylinder, a second-multi-position valve in a first position, and a fluid reservoir, wherein the hydraulic cylinder is affixed to the feeder house; providing, by the pump, a flow of hydraulic fluid through a second plurality of components fluidly coupled together, wherein in a second mode, the second plurality of components comprises the pump, the first-multi-position valve, the cap-end port of the hydraulic cylinder, the piston-end port of the hydraulic cylinder, the second-multi-position valve in a second position, and back to the cap-end port of the hydraulic cylinder, bypassing the fluid reservoir and combining with the flow from a discharge of the pump; and switching between the first position and the second position to enable the switching between the first and second modes, wherein the header is raised by operation of the hydraulic cylinder according to the flow of the hydraulic fluid through the first plurality of components in the first mode and according to the flow of the hydraulic fluid through the second plurality of components in the second mode, wherein the switching occurs with operator intervention.
 12. The method of claim 11, wherein based on the flow of the hydraulic fluid through the second plurality of components in the second mode, the hydraulic cylinder causes the header to raise at a faster speed in the second mode than in the first mode.
 13. The method of claim 11, wherein based on the flow of the hydraulic fluid through the first plurality of components in the first mode, the hydraulic cylinder causes the header to raise with higher force in the first mode than in the second mode.
 14. The method of claim 11, further comprising a second hydraulic cylinder having plural ports and coupled to the hydraulic cylinder in a parallel configuration to receive the hydraulic fluid flows.
 15. The combine harvester of claim 6, wherein based on hydraulic fluid flow in the second fluidic circuit, the hydraulic cylinder causes the header to raise at a faster speed in the second mode than in the first mode.
 16. The combine harvester of claim 6, wherein based on hydraulic fluid flow in the first fluidic circuit, the hydraulic cylinder causes the header to raise with higher force in the first mode than in the second mode.
 17. The combine harvester of claim 6, wherein the control system comprises another multi-port hydraulic cylinder coupled affixed to the feeder house and coupled to the cylinder circuit to enable a raising and lowering of the feeder house and the header. 